438 lines
12 KiB
C++
438 lines
12 KiB
C++
/*
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* This program source code file is part of KiCad, a free EDA CAD application.
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*
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* Copyright (C) 2016 CERN
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* Copyright (C) 2021 KiCad Developers, see AUTHORS.txt for contributors.
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*
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* @author Maciej Suminski <maciej.suminski@cern.ch>
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License
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* as published by the Free Software Foundation; either version 3
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* of the License, or (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, you may find one here:
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* https://www.gnu.org/licenses/gpl-3.0.html
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* or you may search the http://www.gnu.org website for the version 3 license,
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* or you may write to the Free Software Foundation, Inc.,
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* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
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*/
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#include "tuner_slider.h"
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#include <sim/sim_plot_frame.h>
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#include <sch_symbol.h>
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#include <template_fieldnames.h>
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#include <sim/ngspice_helpers.h>
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#include <cmath> // log log1p expm1
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#include <complex> // norm
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// characteristic curves (default: 0B Lin)
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static const struct { double m_law, m_mid; } CURVES[] =
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{
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// same order as choices in m_curve
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{ 1.00, 0.10 }, // 10A Log
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{ 1.00, 0.15 }, // 15A Log
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{ 0.90, 0.13 }, // 15A Log S
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{ 0.00, 0.10 }, // 10C Rev Log
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{ 0.00, 0.15 }, // 15C Rev Log
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{ 0.10, 0.13 }, // 15C Rev Log S
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{ 0.50, 0.50 }, // 0B Lin
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{ 0.50, 0.15 }, // 4B S-Curve
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{ 0.50, 0.10 }, // 5B S-Curve
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{ 0.50, 0.00 } // Switch
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};
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template <typename T, int S>
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static inline int arraysize( const T ( &v )[S] ) { return S; }
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/**
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* Transform ratio according to linear, logarithmic or reverse logarithmic laws
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* (characteristic curve or taper) of rotary or slide potentiometer (pot or fader).
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*
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* Parameters corresponding to *IEC 60393-1:2008* and *JIS C 5260-1* code letters:
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*
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* | @p aLaw | @p aMid | Code | Resistance Law (Taper)
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* | ------: | ------: | ---: | :---------------------
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* | 1.00 | 0.10 | 10A | CW logarithmic
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* | ^ | 0.15 | 15A | CW logarithmic (audio)
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* | 0.90 | 0.13 | ^ | CW logarithmic (high-end audio)
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* | 0.00 | 0.10 | 10C | CCW/reverse logarithmic
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* | ^ | 0.15 | 15C | CCW/reverse logarithmic (reverse audio)
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* | 0.10 | 0.13 | ^ | CCW/reverse logarithmic (high-end reverse audio)
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* | 0.50 | 0.50 | 0B | (ideal) linear
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* | ^ | 0.15 | 4B | symmetric (audio S-curve)
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* | ^ | 0.10 | 5B | symmetric (S-curve)
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* | ^ | 0.00 | - | switch
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*
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* Standards code letters cross-reference:
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*
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* | IEC 60393-1:2008 | IEC 60393-1:1989 | MIL-R-94 | Resistance Law
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* | ----------------: | :--------------: | :------: | :-------------
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* | 0B | A | A | linear
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* | 10A | B | C | logarithmic
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* | 15A | ^ | - | ^
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* | 10C | C | F | reverse logarithmic
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* | 15C | ^ | - | ^
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*
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* **Logarithmic Law** is for *levels* (logarithmic units) and is actually an exponential curve.
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* **Reverse** refers to a reverse-mounted resistive element or shaft on a potentiometer
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* (resulting in a reflected curve). An **S-curve** is a curve joined to its (scaled) reflection,
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* and *may* be symmetric or linear. **Inverse** refers to the mathematical inverse of a function.
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*
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* @tparam F is a floating point type.
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* @param aRatio is the input (travel) ratio or moving contact (wiper) position, from
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* 0%/CCW/left (0) through 50%/mid-travel/center (1/2) to 100%/CW/right (1).
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* @param aMid is the logarithmic laws' output ratio at 50%/mid-travel/center (1/2)
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* input ratio.
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* @param aLaw is the (resistance) law, interpolating from *reverse logarithmic* (0)
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* through *symmetric/linear* (1/2) to *logarithmic* (1).
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* @param aInverse swaps input and output ratios (inverse function, where possible),
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* if @c true.
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* @return the output (resistance or voltage) ratio in [0, 1].
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*/
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template <typename F>
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static F taper( F aRatio, F aMid = 0.5, F aLaw = 1.0, bool aInverse = false )
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{
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static_assert( std::is_floating_point<F>::value, "F must be floating point" );
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// clamp to [0, 1] and short-cut
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if( aRatio <= 0 )
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return 0;
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if( aRatio >= 1 )
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return 1;
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// short-cut for ideal linear or at S-curve inflection point
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if( aMid == 0.5 || aRatio == aLaw )
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return aRatio;
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F t = aRatio;
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// clamp to [0, 1] and short-cut at (non-invertible) limits
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if( aMid <= 0 )
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{
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t = aInverse ? 1 : 0;
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}
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else if( aMid >= 1 )
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{
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t = aInverse ? 0 : 1;
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}
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else
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{
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// clamp, and reflect and/or scale for reverse...symmetric...normal laws
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if( aLaw >= 1 )
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{
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// Do nothing, leave t = t
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}
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else if( aLaw <= 0 )
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{
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t = 1 - t;
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}
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else if( aRatio <= aLaw )
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{
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t = t / aLaw;
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}
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else
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{
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t = ( 1 - t ) / ( 1 - aLaw );
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}
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// scaling factors for domain and range in [0, 1]
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F a = std::norm( 1 - 1 / aMid );
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F b = std::log( a );
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F c = a - 1;
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// scaling: a = (1 - 1/m)^2
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// log law: (a^t - 1) / (a - 1)
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// inverse: log_a(1 + t (a - 1))
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t = aInverse ? ( std::log1p( t * c ) / b ) : ( std::expm1( t * b ) / c );
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}
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// clamp, and scale and/or reflect for reverse...symmetric...normal laws
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if( aLaw >= 1 )
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{
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// Do nothing, leave t = t
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}
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else if( aLaw <= 0 )
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{
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t = 1 - t;
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}
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else if( aRatio <= aLaw )
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{
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t = t * aLaw;
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}
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else
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{
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t = 1 - t * ( 1-aLaw );
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}
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return t;
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}
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TUNER_SLIDER::TUNER_SLIDER( SIM_PLOT_FRAME* aFrame, wxWindow* aParent, SCH_SYMBOL* aSymbol ) :
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TUNER_SLIDER_BASE( aParent ),
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m_symbol( aSymbol ),
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m_fieldId( MANDATORY_FIELD_T::VALUE_FIELD ),
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m_min( 0.0 ),
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m_max( 0.0 ),
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m_value( 0.0 ),
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m_changed( false ),
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m_frame ( aFrame )
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{
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// TODO.
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/*const wxString compName = aSymbol->GetField( REFERENCE_FIELD )->GetText();
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m_name->SetLabel( compName );
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m_spiceTuningCommand = aFrame->GetExporter()->GetSpiceTuningCommand( compName );
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if( m_spiceTuningCommand.second )
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{
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// model parameter, with fixed %-range and unknown initial value
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m_min = 0;
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m_max = 100;
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m_value = ( m_max - m_min ) / 2.0; // midpoint
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m_minText->Disable();
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m_maxText->Disable();
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m_saveBtn->Disable(); // not an instance parameter that could be updated (invalid m_fieldId)
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}
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else
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{
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// instance parameter
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if( aSymbol->FindField( netlist_exporter_spice::GetSpiceFieldName( SF_MODEL ) ) )
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m_fieldId = aSymbol->FindField( netlist_exporter_spice::GetSpiceFieldName( SF_MODEL ) )->GetId();
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else
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m_fieldId = aSymbol->GetField( VALUE_FIELD )->GetId();
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m_value = SPICE_VALUE( aSymbol->GetFieldById( m_fieldId )->GetText() );
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m_min = SPICE_VALUE( 0.5 ) * m_value;
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m_max = SPICE_VALUE( 2.0 ) * m_value;
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}
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// Call Set*() methods to update fields and slider
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m_minText->SetValue( m_min.ToOrigString() );
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m_maxText->SetValue( m_max.ToOrigString() );
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updateValueText();
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updateSlider();
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m_simTimer.SetOwner( this );
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Connect( wxEVT_TIMER, wxTimerEventHandler( TUNER_SLIDER::onSimTimer ), nullptr, this );*/
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}
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bool TUNER_SLIDER::SetValue( const SPICE_VALUE& aVal )
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{
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// Get the value into the current range boundaries
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if( aVal > m_max )
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m_value = m_max;
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else if( aVal < m_min )
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m_value = m_min;
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else
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m_value = aVal;
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updateValueText();
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updateSlider();
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updateComponentValue();
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return true;
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}
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bool TUNER_SLIDER::SetMin( const SPICE_VALUE& aVal )
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{
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if( aVal >= m_max )
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return false;
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m_min = aVal;
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if( m_value < aVal ) // Limit the current value
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SetValue( aVal );
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m_minText->SetValue( aVal.ToOrigString() );
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updateSlider();
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return true;
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}
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bool TUNER_SLIDER::SetMax( const SPICE_VALUE& aVal )
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{
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if( aVal <= m_min )
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return false;
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m_max = aVal;
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if( m_value > aVal ) // Limit the current value
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SetValue( aVal );
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m_maxText->SetValue( aVal.ToOrigString() );
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updateSlider();
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return true;
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}
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void TUNER_SLIDER::updateComponentValue()
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{
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// Start simulation in 100 ms, if the value does not change meanwhile
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m_simTimer.StartOnce( 100 );
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}
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void TUNER_SLIDER::updateSlider()
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{
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wxASSERT( m_max >= m_value && m_value >= m_min );
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int choice = m_curve->GetSelection();
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wxCHECK( choice >= 0 && choice < arraysize( CURVES ), /*void*/ );
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double ratio = ( ( m_value - m_min ) / ( m_max - m_min ) ).ToDouble();
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double travel = taper( ratio, CURVES[choice].m_mid, CURVES[choice].m_law, true );
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m_slider->SetValue( KiROUND( travel * 100.0 ) );
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}
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void TUNER_SLIDER::updateValueText()
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{
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bool spiceString = m_min.IsSpiceString() || m_max.IsSpiceString();
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m_valueText->SetValue( spiceString ? m_value.ToSpiceString() : m_value.ToString() );
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}
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void TUNER_SLIDER::updateMax()
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{
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try
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{
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SPICE_VALUE newMax( m_maxText->GetValue() );
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SetMax( newMax );
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}
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catch( const KI_PARAM_ERROR& )
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{
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// Restore the previous value
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m_maxText->SetValue( m_max.ToOrigString() );
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}
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}
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void TUNER_SLIDER::updateValue()
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{
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try
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{
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SPICE_VALUE newCur( m_valueText->GetValue() );
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SetValue( newCur );
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m_changed = true;
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}
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catch( const KI_PARAM_ERROR& )
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{
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// Restore the previous value
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m_valueText->SetValue( m_value.ToOrigString() );
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}
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}
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void TUNER_SLIDER::updateMin()
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{
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try
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{
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SPICE_VALUE newMin( m_minText->GetValue() );
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SetMin( newMin );
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}
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catch( const KI_PARAM_ERROR& )
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{
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// Restore the previous value
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m_minText->SetValue( m_min.ToOrigString() );
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}
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}
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void TUNER_SLIDER::onClose( wxCommandEvent& event )
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{
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m_frame->RemoveTuner( this );
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}
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void TUNER_SLIDER::onSave( wxCommandEvent& event )
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{
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m_frame->UpdateTunerValue( m_symbol, m_fieldId, m_value.ToOrigString() );
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}
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void TUNER_SLIDER::onSliderChanged( wxScrollEvent& event )
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{
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int choice = m_curve->GetSelection();
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wxCHECK( choice >= 0 && choice < arraysize( CURVES ), /*void*/ );
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double travel = m_slider->GetValue() / 100.0;
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double ratio = taper( travel, CURVES[choice].m_mid, CURVES[choice].m_law, false );
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m_value = m_min + ( m_max - m_min ) * SPICE_VALUE( ratio );
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updateValueText();
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updateComponentValue();
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m_changed = true;
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}
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void TUNER_SLIDER::onCurveChoice( wxCommandEvent& event )
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{
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updateValue();
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}
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void TUNER_SLIDER::onMaxKillFocus( wxFocusEvent& event )
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{
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updateMax();
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event.Skip(); // Mandatory in wxFocusEvent
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}
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void TUNER_SLIDER::onValueKillFocus( wxFocusEvent& event )
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{
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updateValue();
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event.Skip(); // Mandatory in wxFocusEvent
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}
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void TUNER_SLIDER::onMinKillFocus( wxFocusEvent& event )
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{
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updateMin();
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event.Skip(); // Mandatory in wxFocusEvent
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}
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void TUNER_SLIDER::onMaxTextEnter( wxCommandEvent& event )
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{
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updateMax();
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event.Skip(); // Mandatory in wxFocusEvent
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}
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void TUNER_SLIDER::onValueTextEnter( wxCommandEvent& event )
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{
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updateValue();
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}
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void TUNER_SLIDER::onMinTextEnter( wxCommandEvent& event )
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{
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updateMin();
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}
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void TUNER_SLIDER::onSimTimer( wxTimerEvent& event )
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{
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if( m_changed )
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{
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wxQueueEvent( m_frame, new wxCommandEvent( EVT_SIM_UPDATE ) );
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m_changed = false;
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}
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}
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